The hemispheric distribution of Torpedo nicotinic receptors expressed in Xenopus oocytes

Response to lysophosphatidic acid in Xenopus oocytes and its rapid desensitization: the role of Gq and Go G-protein families

Native Xenopus oocytes exhibit dose-dependent depolarizing current responses to lysophosphatidic acid (LPA), with EC50 = 0.18 microM. Responses to LPA were subject to pronounced rapid desensitization. When oocytes were challenged with 5 nM LPA, the response was <10% of the maximal. Subsequent addition of 0.5 microM LPA resulted in 50-70% desensitization, when compared to naïve controls. Injection of antisense oligodeoxyoligonucleotides (ASODNs) targeted at either of the two endogenous LPA receptors inhibited the LPA response by approximately 50%, but did not alter the degree of rapid desensitization. To study the involvement of G-proteins in rapid homologous desensitization of responses to LPA, we selectively depleted native G-proteins by injection of specific ASDONs. Injection of ASDONs targeted at Galphaq family mRNAs (mainly Galpha11) reduced the response to 0.5 microM LPA by 50%. ASDONs targeted at either Galphao or Galphao1 caused a large decrease in the amount of their cognate mRNAs and the Galphao family proteins, while the response to LPA was inhibited by up to 30%. Injection of ASDONs targeted at Galphao1 mRNA decreased rapid desensitization from 69 to 23%, while pertussis toxin (PTX) completely abolished it. Expression of two dominant negative mutants of the human Galphao family homologs either decreased or virtually abolished rapid desensitization. Microinjection of CaCl(2) demonstrated that 50% of rapid desensitization could be attributed to inhibition of Ca(2+) activation of chloride channels. We propose that the apparent degenerate coupling of different G-proteins to LPA receptors in Xenopus oocytes actually serves both the generation of the response (by Gq and Go G-protein families) and its desensitization (mostly by Go G-protein family).

A novel crystallization method for visualizing the membrane localization of potassium channels

The high permeability of K+ channels to monovalent thallium (Tl+) ions and the low solubility of thallium bromide salt were used to develop a simple yet very sensitive approach to the study of membrane localization of potassium channels. K+ channels (Kir1.1, Kir2.1, Kir2.3, Kv2.1), were expressed in Xenopus oocytes and loaded with Br ions by microinjection. Oocytes were then exposed to extracellular thallium. Under conditions favoring influx of Tl+ ions (negative membrane potential under voltage clamp, or high concentration of extracellular Tl+), crystals of TlBr, visible under low-power microscopy, formed under the membrane in places of high density of K+ channels. Crystals were not formed in uninjected oocytes, but were formed in oocytes expressing as little as 5 microS K+ conductance. The number of observed crystals was much lower than the estimated number of functional channels. Based on the pattern of crystal formation, K+ channels appear to be expressed mostly around the point of cRNA injection when injected either into the animal or vegetal hemisphere. In addition to this pseudopolarized distribution of K+ channels due to localized microinjection of cRNA, a naturally polarized (animal/vegetal side) distribution of K+ channels was also frequently observed when K+ channel cRNA was injected at the equator. A second novel "agarose-hemiclamp" technique was developed to permit direct measurements of K+ currents from different hemispheres of oocytes under two-microelectrode voltage clamp. This technique, together with direct patch-clamping of patches of membrane in regions of high crystal density, confirmed that the localization of TlBr crystals corresponded to the localization of functional K+ channels and suggested a clustered organization of functional channels. With appropriate permeant ion/counterion pairs, this approach may be applicable to the visualization of the membrane distribution of any functional ion channel.

The hemispheric functional expression of the thyrotropin-releasing-hormone receptor is not determined by the receptors' physical distribution

The thyrotropin-releasing-hormone receptor (TRH-R) is a member of a family of the G-protein-coupled receptors that share structural similarities and exert their physiological action via the inositol lipid signal-transduction pathway. The TRH-R when expressed in Xenopus oocytes exhibits marked preference of the response (increased chloride conductance) for the animal hemisphere. Whereas the rat TRH-R functional distribution was strongly asymmetric (animal/vegetal ratio = 9.5), the mouse TRH-R exhibited a significantly lower ratio (3.9). Truncation of the last 59 amino acids of the C-terminal region of the mouse TRH-R did not lead to any changes in the functional hemispheric distribution. Despite the polarization of response, receptor number was similar on both hemispheres. Moreover, the apparent half-life of the functional expression of the TRH-R was approx. 4 h on both hemispheres when the expression was inhibited by a specific antisense oligonucleotide. Inhibition of total protein synthesis with cycloheximide affected hemispheric responses mediated by each of the three TRH-Rs tested in a qualitatively different way. These results suggest that an additional, rapidly degraded, protein modulates the functional hemispheric expression of the TRH-Rs.